DE60216850T2 - Intake system for axial piston pump - Google Patents

Description

technical area

The The present invention relates generally to axial piston pumps and more particularly to an axial piston variable delivery pump with an inlet filling on the outer diameter via a drive plate with a fixed angle.

background

The in US Pat. No. 6,035,828 to Anderson et al. A. described invention shows a pump with variable delivery and fixed displacement. Anderson discloses also a drive plate with a fixed angle and an electronic Control unit that can change the effective fluid displacement, which is reached by each pump stroke. This construction had particular success and represents a significant improvement over previous systems but there is room for improvement.

For example Anderson's drive plate is mounted on tapered roller bearings, to ensure a gentle turn. While this construction theirs Purpose achieved is a considerable amount of torque wasted in overcoming the friction of the roller bearings. In addition are Tapered roller bearings are relatively expensive and subject to failure, such as any other movable metallic component. It would be like that desirable, to reduce the cost and friction between the drive plate and the pump housing. Additionally finds the refilling of the interior of the hollow piston by drawing fluid from the low-pressure interior of the pump via an opening in the outer radius the drive plate instead. Consequently, the engine power that is used is less to supply the pump with hydraulic fluid as complete exploited, which has a reduction in the efficiency result. It would be thus desirable, to use a construction, the advantage of the inlet pressure of hydraulic fluid draws.

The U.S. Patent 3,847,057 discloses an axial pump whose rotating one Cylinder block has cylinder chambers and pistons therein with an end face cylinder ports that has a stationary control face work together that has high pressure and low pressure connections. A closed interior in the housing is provided by pressure limiting throttling means held at an intermediate pressure when using leakage fluid filled becomes. Control means having lines connect the closed one Interior with a cylinder chamber, if the respective cylinder connection located at a control end face portion between the high pressure and low pressure ports is at an intermediate pressure, and separate the closed interior from the cylinder chambers when the cylinder connections with the high pressure and Low-pressure connections communicate in the control face.

The U.S. Patent 3,890,883 also discloses an axial piston pump with stationary and rotating control end faces, with inlet and outlet ports and with respective cylinder connections are formed. A swash plate is provided and determined withdrawn and advanced dead center positions of the pistons in an axial direction Level. The inlet port has an end which is closer to the Level in the region of withdrawn Dead center position is located, than half of the round of each Cylinder connection, allowing each cylinder port to the inlet port also communicates after the respective piston on the withdrawn Dead center position has run and begins to advance to the To move dead center position. In this way, the respective Cylinder completely filled while the Center of the respective cylinder connection over an angle between 5 ° and 20 ° over the Level of death points moved. The other end of the inlet connection can also be closer from the level of dead center positions as half the circumference of each Cylinder connection be spaced.

According to the present Invention, a pump according to claim 1 is provided. Preferred embodiments The invention are disclosed in the dependent claims Un.

The The present invention is directed to one or more of the To overcome problems or disadvantages which are set out above.

Summary the invention

According to one Aspect is a drive plate for an axial piston pump provided with a metal component has a centerline and a drive surface other than 90 degrees relative to the center line. The metal component has further on a radial outer surface, which surrounds the centerline and defines a fill passage that extends between the radial outer surface and the drive surface extends. The filling passage has an annular Groove, which is defined by the radial outer surface.

In another aspect, a pump is provided having a housing defining an inlet. A plurality of pistons are provided, each defining a hollow interior and disposed about a centerline. A rotatable drive plate is also provided and defines a fill passage extending between a radially outer surface and a drive surface. The hollow interior spaces of the plurality of pistons are in fluid communication with the inlet via an annular groove defined by the housing and / or the drive plate.

According to one more Another aspect is a method of pumping fluid provided with the step, a plurality of pistons at least partially by rotation of a drive plate back and forth to move. The method also includes the step of fluidly Pump, part of the piston with an inlet through an annular groove to join, which is part of a filling passage, which itself between a radial outer surface and a drive surface the drive plate extends. The method also includes the step on, fluid one Pump chamber from another part of the piston with an outlet too connect.

Short description the drawings

1 Figure 3 is a partially sectioned diagrammatic isometric view of a pump according to the present invention;

2 Fig. 11 is a plan view of the drive plate provided in the present invention;

3 is a sectional side view of the drive plate, as along the section line 3-3 of 2 to see;

4 is a sectional bottom view of the drive plate, as along the section line 4-4 of 3 to see.

detailed description

Regarding 1 is there an axial piston pump 1 shown in accordance with the present invention. The pump 1 has a housing 3 and an electro-hydraulic control unit 32 on. A front flange 5 and an end cap 7 are provided and are on the housing 3 attached to opposite ends. An inlet 8th from the case 3 is defined, allows hydraulic fluid to the pump 1 from an external source (not shown). A drum arrangement 18 is provided, which is a drum 19 at least partially in the housing 3 which is preferably adjacent one end of a plurality of pistons 20 is. A drive plate 12 , which is preferably made of metal, is positioned adjacent to the opposite end. A rotatable drive shaft 9 is on the drive plate 12 attached and is by a warehouse 10 carried. The drive shaft 9 is preferably coupled directly to the output of a motor (not shown) so that the rate of rotation of the shaft 9 and the drive plate 12 is directly proportional to the speed of the motor drive shaft.

In the preferred embodiment, the plurality of pistons 20 in parallel orientation about a centerline 11 arranged. Every single piston 20 defines a hollow interior 21 and is about a ball joint 36 on a shoe or slider 34 attached, which in contact with the drive plate 12 is positioned. The hollow interior 21 is a part of the pump chamber for the piston. Return springs 25 continuously push each piston 20 to the drive plate 12 in a conventional manner, so that the pistons sliders 34 in continuous contact with the drive plate 12 stay. The drive plate 12 has a fixed angle β (see 3 ), and its rotation causes the plurality of pistons 20 move sequentially between an upper and a lower position, which displaces fluid in a conventional manner. Because every piston slide 34 kept in contact with the drive plate, the hollow interiors 21 the piston allow fluid to flow across the drive plate 12 is supplied (described below) from an opening 37 in every slider 34 to the opposite end of the piston 20 flows. From this point, the fluid can flow through a check valve 26 in a collection ring 48 be pressed, and from there to an outlet via an outlet passage 29 ,

A sleeve 24 is movable around each of the plurality of pistons 20 assembled. The position of the sleeve 24 Determines the proportion of displacing fluid to the collection ring 28 flows, and the proportion leading to the low-pressure interior 52 the pump 1 flows. Every sleeve 24 is on a connector 22 attached, the drive shaft 9 surrounds. The connector 22 is between an upper and a lower position by the electro-hydraulic control unit 32 movable in a conventional manner, allowing a simultaneous movement of all sleeves 24 allowed. If the sleeve 24 in their lower position, can have a variety of overflow ports 30 fluidly the hollow piston interior spaces 21 with the low-pressure interior 52 connect when the pistons 20 run upwards during a pump stroke. In their upper position, the sleeves cover 24 the overflow connections 30 and allow a pressure in the piston interiors 21 builds up, which has the consequence that a comparatively larger proportion of the fluid through the check valve 26 and in the collection ring 28 by the pumping action of the pistons 20 is pressed. Because the electro-hydraulic control unit 32 Can be used to adjust the vertical position of each sleeve 24 on their respective pistons 20 can control the relative displacement of the pump 1 by ge be controlled that selectively allows the sleeve 24 the overflow connections 30 cover or expose during other parts of a piston pump stroke. The electrohydraulic control unit 32 returns to the initial position via a spring 69 back, when not energized, around the piston sleeves 24 in its lower position, in which the pump does not produce high pressure output.

Additionally with respect to the 2 - 4 is there the metallic drive plate 12 of the present invention. The drive plate 12 has a centerline 11 and a radial inner surface 61 and a radial outer surface 62 that the centerline 11 surrounds. A drive surface 63 extends between the outer surface 62 and the inner surface 61 and is oriented at a drive angle β other than 90 degrees relative to the centerline 11 should be. The drive plate 12 defines a fill passage 60 extending between the radial outer surface 62 and the drive surface 63 extends. The filling passage 60 has an annular groove 71 on, preferably around the radial outer surface 62 machined around, and a fill slot 65 , which is the driving surface 63 opens. It should be noted that the present invention could be designed so that the groove 71 at least partially through the housing 3 would be defined and not by the drive plate 12 itself. The cross-sectional area of the groove 71 should have a sufficient flow area to meet the fluid pumping and carrying requirements of the pump. The part of the filling passage 60 who is the groove 71 and the fill slot 65 may be constructed in any suitable manner as long as an adequate flow area is provided. For example, the present invention shows a variety of spoke-type bores. It should be understood, however, that some other design could be used, such as a continuous slot through the radially outer surface 62 , In the preferred embodiment from the filling slot 65 arcuate and follow a path that has a substantially constant radius, a circle 66 , relative to the center line 11 , and preferably pivoted over an angle δ, which is less than 180 degrees. If the drive plate 12 turns, is the hollow interior 21 of at least one of the plurality of pistons 20 in fluid communication with the inlet 8th over the filling passage 60 and the annular groove 71 ,

A base area 64 is opposite to the drive surface 63 located and separates the radial inner surface 61 from the radial outer surface 62 , The base area 64 is preferably in a plane substantially perpendicular to the center line 11 is, and is from the housing 3 through a fluid axial bearing 43 separated. An axial bearing plate 40 containing a variety of pressure pad or axial pad 42 is under the fluid pressure bearing or fluid thrust bearing 43 ( 1 ) and the drive plate 12 positioned. The drive plate 12 defines a variety of storage supply passages 67 that differ from the base area 64 through the drive surface 63 extend and the fluid for the thrust bearing 43 deliver. The storage supply passages 67 are preferably on a circle 66 distributed on the midline 11 is centered, and includes the bow that extends from the fill slot 65 is swept over. In the preferred embodiment, a major portion of the radially outer surface 62 a part of a regular cylinder and is from the housing 3 through a fluid plain bearing 44 separated. Hydraulic fluid enters the area between the radial outer surface 62 and the housing 3 pressed to the (radial) plain bearing 44 to supply. Although preferred, it is not necessary for the present invention to include both fluid thrust bearings and fluid radial bearings. A conventional rolling bearing could be used for any of the fluid bearings provided by the present invention.

industrial applicability

Now again referring to 1 causes the rotation of the drive plate 12 that the pistons are 20 Move up and down by lifting and lowering the sliders 34 from each piston 20 when the plate passes underneath. The axial loads generated by the reciprocating motion of the piston may be from the plurality of pressure pads or axial pads 42 be compensated. If the drive plate 12 under one of the pistons 20 passes, the drive surface can 63 on the piston shoe or the Kolbengleitstück 34 act to the piston 20 to drive up for a pumping stroke. Each slider 34 is with his respective piston 20 through a ball joint 36 connected, which allows the slider 34 in continuous contact with the drive surface 63 remains. The amount of fluid flowing from the piston 20 in the high-pressure collecting ring 28 is displaced depends on the position of its respective sleeve 24 from. If a comparatively larger fluid displacement is desired, the electro-hydraulic control unit may 32 used to the sleeves 24 to move upwards. The pods 24 then cover the overflow connections 30 , and a maximum amount of fluid may be from the pumping stroke of each piston 20 be displaced to over the check valve 26 in the collection ring 28 to flow. By varying the time for which the pods 24 held at their upper position, thus, a wide range of fluid displacement amounts can be achieved.

If the drive plate 12 the piston 20 Having moved to its maximum displacement, it begins to move down, being its slider 34 in continuous contact with the drive surface 63 remains. Shortly after the piston 20 begins to retract, brings the rotation of the drive plate 12 the filling slot 65 under the opening 37 in piston shoes or Kolbengleitstück 34 , Because fluid flows continuously across the inlet 8th to the filling passage 60 is delivered, the return movement of the piston acts 20 in that they contain fluid from the filling slot 65 in his hollow interior 21 draws. Because the filling passage 60 with hydraulic fluid directly from the inlet 8th and not from the low-pressure interior 52 the pump 1 is delivered, fluid is in the hollow interior 21 the piston pulled in more easily than prior art pumps. The low-pressure interior 52 is preferably fluidly with the inlet 8th connected via a pressure compensating passage, which is not shown. Just before the piston 20 reaches its fully retracted position, moves the rotation of the drive plate 12 the filling slot 65 except fluid connection with the opening 38 in the piston sliding piece 34 ,

If the drive plate 12 turns, fluid is flowing across the inlet 8th is delivered, in the area between the radial outer surface 62 the drive plate 12 and the housing 3 pressed what a fluid plain bearing 44 with relatively low friction result. The storage supply passages 67 that fluidly the drive surface 63 with the base area 64 connect, allow a continuous fluid supply to the area between the drive plate 12 and the thrust bearing plate or thrust bearing plate 40 is delivered, which is the fluid thrust bearing 43 forms the invention. In other words, a part of the fluid, which is from the piston 20 is pumped through the storage supply passages 67 pressed to a fluid thrust bearing 43 to generate which the drive plate 12 that of a contact with the pressure pad 42 separates. The replacement of conventional rolling bearings by the fluid radial bearings 44 and fluid bearings 43 allows the present invention to be manufactured at a lower cost and to operate with a considerably reduced frictional load. The present invention represents a further improvement over previous designs in that it takes advantage of the fluid supply pressure at the inlet 8th helping to replenish the hydraulic fluid in the pistons and not relying on the reciprocating action of the pistons 20 leaves to fluid back into their interiors 21 to draw.

The the above description is for illustrative purposes only and is not intended to limit the scope of the present invention in any way Limit the way. For example, could the fluid bearing design, which is used in the present invention, be modified to create a combination of fluid and to use roller bearings. In addition, the construction of the drive plate filling passage could as a means of reducing the piping in a pump with Space limitations are used.

Claims (9)

Pump ( 1 ) comprising: a housing ( 3 ) with an inlet ( 8th ); a variety of pistons ( 20 ) around a midline ( 11 ) and each of the pistons ( 20 ) a hollow interior ( 21 ) Has; a rotatable drive plate ( 12 ) with a filling passage ( 60 ) disposed therein and extending between a radially outer surface ( 62 ) and a drive surface ( 12 ), and wherein the filling passage ( 60 ) an annular groove ( 71 ), which in the housing ( 3 ) or in the drive plate ( 12 ) is arranged; the hollow interior ( 21 ) of at least one of the plurality of pistons ( 20 ) in fluid communication with the inlet ( 8th ) via the filling passage ( 60 ) by the rotation of the rotatable drive plate ( 12 ). Pump ( 1 ) according to claim 1, which is a drum ( 19 ) which at least partially in the housing ( 3 ) adjacent one end of the plurality of pistons ( 20 ) is positioned; the plurality of pistons ( 20 ) parallel to the center line ( 11 ) is oriented; the drive plate ( 12 ) a drive surface ( 63 ) which is adjacent to an opposite end of each of the plurality of pistons (FIG. 20 ) is positioned. Pump ( 1 ) according to claim 1, wherein the drive plate ( 12 ) a base surface ( 64 ), that of the housing ( 3 ) through a fluid thrust bearing ( 43 ) is separated; and wherein the drive plate ( 12 ) a radial outer surface ( 62 ), that of the housing ( 3 ) through a fluid plain bearing ( 44 ) is disconnected. Pump ( 1 ) according to claim 1, wherein the drive plate ( 12 ) a large number of stock supply passages ( 67 ) defined between the base surface ( 64 ) by the drive surface ( 63 ). Pump ( 1 ) according to claim 1, wherein a main part of the radial outer surface ( 62 ) is part of a regular cylinder. Pump ( 1 ) according to claim 5, wherein a part of the filling passage ( 60 ) a filling slot ( 65 ) by the drive surface ( 63 ); and wherein the filling slot ( 65 ) an arc with a substantially constant radius relative to the center line ( 11 ) follows. Pump ( 1 ) according to claim 6, wherein the annular groove ( 71 ) through the drive plate ( 12 ) is defined. Pump ( 1 ) according to claim 1, wherein the drive plate ( 12 ) a base surface ( 64 ) having a radial inner surface ( 61 ) from the radial outer surface ( 62 ) separates; the filling passage ( 60 ) an arcuate filling slot ( 65 ) by the drive surface ( 63 ), and wherein the filling slot ( 65 ) at an angle (δ) of less than 180 ° about the center line ( 11 ) is available; and wherein the drive plate ( 12 ) a plurality of storage supply passages ( 67 ) defined by the base area ( 64 ) by the drive surface ( 63 ). Pump ( 1 ) according to claim 8, wherein the storage supply passages ( 67 ) and the filling slot ( 65 ) on a circle ( 66 ) distributed on the midline ( 11 ) is centered; where the base area ( 64 ) in a plane substantially perpendicular to the center line ( 11 ) lies; and wherein a main part of the radial outer surface ( 62 ) is part of a regular cylinder.